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Chemical characterisation of benzene oxidation products under
high and low NOx conditions using chemical ionisation mass
spectrometry
Michael Priestley1*, Thomas J. Bannan1, Michael Le Breton1†, Stephen D. Worrall1=, Sungah Kang2, Iida
Pullinen2+, Sebastian Schmitt2, Ralf Tillmann2, Einhard Kleist7, Defeng Zhao2-, Jürgen Wildt2,7, Olga 5
Garmash4, Archit Mehra1ˆ, Asan Bacak1~, Dudley E. Shallcross3,5, Åsa Halquist8, Mikael Ehn4, Astrid
Kiendler-Scharr2, Thomas F. Mentel2, Gordon McFiggans1, Mattias Halquist6, Hugh Coe1, Carl J.
Percival1‖
1Centre for Atmospheric Science, Department of Earth and Environmental Sciences, University of Manchester,
Manchester, M13 9PL, UK 10
2Institut für Energie und Klimaforschung, IEK-8, Forschungszentrum Jülich, Jülich, Germany
3School of Chemistry, The University of Bristol, Cantock’s Close BS8 1TS, UK
4Institute for Atmospheric and Earth System Research/Physics, Faculty of Science, University of Helsinki, 00014
Helsinki, Finland
5Department of Chemistry, University of the Western Cape, Bellville, South Africa 15
6Department of Chemistry and Molecular Biology, University of Gothenburg, 412 96, Gothenburg, Sweden (*
Now at)
7Institut für Bio- und Geowissenschaften, IBG-2: Pflanzenwissenschaften,Forschungszentrum Jülich GmbH,
Jülich, Germany
8IVL Swedish Environmental Research Institute, Gothenburg, Sweden 20
‖ Now at Jet Propulsion Laboratory, 4800 Oak Grove Drive, Pasadena, CA 91109
+ Now at Department of Applied Physics, University of Eastern Finland, 702132 Kuopio, Finland
= Now at Aston Institute of Materials Research, School of Engineering and Applied Science, Aston University,
Birmingham, B4 7ET, UK 25
† Now at Volvo Group Trucks Technology, L3 Lundby, Gothenburg, Sweden
~ Now at Turkish Accelerator & Radiation Laboratory, Ankara University, Institute of Accelerator,
Technologies Gölbaşı Campus, 06830 Golbasi / Ankara, Turkey
ˆ Now at Faculty of Science and Engineering, University of Chester, CH2 4NU, UK
- Now at Department of Atmospheric and Oceanic Sciences & Institute of Atmospheric Sciences, Fudan 30
University, Shanghai, China
Corresponding author: Michael Priestley (michael.priestley@gu.se)
Abstract
Aromatic hydrocarbons are a class of volatile organic compounds associated with anthropogenic activity and 35
make up a significant fraction of urban VOC emissions that contribute to the formation of secondary organic
aerosol (SOA). Benzene is one of the most abundant species emitted from vehicles, biomass burning and industry.
An iodide time of flight chemical ionisation mass spectrometer (ToF-CIMS) and nitrate ToF-CIMS were deployed
https://doi.org/10.5194/acp-2020-819Preprint. Discussion started: 17 August 2020c© Author(s) 2020. CC BY 4.0 License.
2
at the Jülich plant chamber as part of a series of experiments examining benzene oxidation by OH under high and
low NOx conditions, where a range of organic oxidation products were detected. The nitrate scheme detects many 40
oxidation products with high masses ranging from intermediate volatile organic compounds (IVOC) to extremely
low volatile organic compounds (ELVOC), including C12 dimers. In comparison, very few species with C≥6 and
O≥8 were detected with the iodide scheme, which detected many more IVOC and semi volatile organic compounds
(SVOC) but very few ELVOC and low volatile organic compounds (LVOC). 132 and 195 CHO and CHON
oxidation products are detected by the iodide ToF-CIMS in the low and high NOx experiments respectively. Ring 45
breaking products make up the dominant fraction of detected signal (89 – 91%). 21 and 26 of the products listed
in the master chemical mechanism (MCM) were detected and account for 6.4 – 7.3 % of total signal. The time
series of highly oxidised (O≥6) and ring retaining oxidation products (C6 and double bond equivalent = 4)
equilibrate quickly characterised by a square form profile, compared to MCM and ring breaking products which
increase throughout oxidation exhibiting saw tooth profiles. Under low NOx conditions, all CHO formulae 50
attributed to radical termination reactions of 1st generation benzene products and 1st generation autoxidation
products are observed, and one exclusively 2nd generation autoxidation product is also measured (C6H8O8). Several
N containing species that are either 1st generation benzene products or 1st generation autoxidation products are
also observed under high NOx conditions. Hierarchical cluster analysis finds four cluster of which two describe
photo-oxidation. Cluster 2 shows a negative dependency on the NO2/NOx ratio indicating it is sensitive to NO 55
concentration thus likely to contain NO addition products and alkoxy derived termination products. This cluster
has the highest average carbon oxidation state (OS𝐶 ) and the lowest average carbon number and where nitrogen
is present in cluster member, the oxygen number is even, as expected for alkoxy derived products. In contrast,
cluster 1 shows no dependency on the NO2/NOx ratio and so is likely to contain more NO2 addition and peroxy
derived termination products. This cluster contains less fragmented species, as the average carbon number is 60
higher and OS𝐶 lower than cluster 2, and more species with an odd number of oxygen atoms. This suggests
clustering of time series which have features pertaining to distinct chemical regimes e.g. NO2/NOx perturbations,
coupled with a priori knowledge, can provide insight into identification of potential functionality.
1. Introduction
Benzene is an aromatic volatile organic compound (VOC) commonly used as a vehicular fuel additive (Verma 65
and Des Tombe, 2002) and as a chemical intermediate in the manufacture of a range of products e.g. detergents
(Oyoroko and Ogamba, 2017), lubricants (Rodriguez et al., 2018), dyes (Guo et al., 2018) and pesticides (Wang
et al., 2014). Whilst current global estimates of benzenoid (molecules containing a benzene ring) emission to the
atmosphere by vegetation is of a comparable order to that of anthropogenic activity (~ 5 times lower, Misztal et
al. 2015), and background concentrations of benzene are enhanced by increased biomass burning (Archibald et 70
al., 2015), emission of benzene to the urban atmosphere is dominated by vehicle exhausts (Gentner et al., 2012)
and solvent evaporation (Hoyt and Raun, 2015). As well as a toxin (Snyder, Kocsis and Drew, 1975) and
carcinogen (Ruchirawat et al., 2005, 2007; Bird et al., 2010), benzene is photochemically active and contributes
to the formation of ozone (O3) and secondary organic aerosol (SOA), both of which act to modify the climate and
contribute to poor air quality (Henze et al., 2007; Ng et al., 2007). SOA formation from benzene has previously 75
been quantified with a focus on the contribution from smaller mass, ring breaking reaction products such as
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3
epoxides (Glowacki, Wang and Pilling, 2009) and dicarbonyl aldehydes (Johnson et al., 2005). For example the
37% of the glyoxal formed in the LA basin is estimated to derive from aromatic sources (Knote et al., 2014).
These smaller ring breaking products typically make up a larger fraction of SOA mass than the ring retaining
products (Borrás and Tortajada-Genaro, 2012) and so have traditionally been the main focus for SOA 80
quantification. Other major, toxic benzene oxidation products such as catechol, nitrophenol and maleic anhydride
are also known components of SOA (Borrás and Tortajada-Genaro, 2012).
More recently the autoxidation mechanism has been demonstrated to occur in aromatic systems (Wang et al.,
2017, Wang et al., 2020; Molteni et al., 2018; Tsiligiannis et al., 2019; Garmash et al., 2020; Mehra et al., 2020)
producing highly oxygenated organic molecules (HOM, defined as containing 6 or more oxygen atoms which is 85
a product of the autoxidation mechanism) incorporating up to 11 oxygen atoms (Bianchi et al., 2019). The
autoxidation mechanism of intra molecular H shifts from the carbon backbone to the peroxy radical centre forming
peroxide groups is consistent with other VOC systems (Rissanen et al., 2014) initiated by a variety of different
oxidants (e.g. Mentel et al. 2015; Berndt et al. 2016). The inclusion of an alkyl group to a benzene ring facilitates
HOM formation (Wang et al., 2017) as a consequence of the greater degrees of freedom afforded to the molecule. 90
Whilst benzene is not the most reactive of aromatic VOCs, τOH ≈ 9.5 days for benzene vs. τOH ≈ 6-10 hours for
xylenes ([OH] = 2.0 × 106 molecules cm-3, Atkinson and Arey, (2007)), it is ubiquitous in the urban environment
and is the simplest C6 aromatic ring system to study.
Oxidation of benzene occurs nearly exclusively via hydroxyl radical (OH) addition to form the cyclohexadienyl
radical/benzene-OH adduct, which subsequently adds O2 to form the hydroxycyclohexadiene peroxy radical 95
(C6H6-OH-O2) (Volkamer et al., 2002) (Fig. 1). Two subsequent reaction pathways are postulated for this peroxy
radical: either elimination of HO2 yields phenol and secondary OH attack must occur again; or an endocyclic di-
oxygen bridged carbon centred radical intermediate is formed by the addition of the peroxy group to (typically a
β-carbon (Glowacki, Wang and Pilling, 2009)). This di-oxygen bridge carbon centred radical may add another O2
and form a peroxy radical (named as BZBIPERO2 in the master chemical mechanism, MCM, Saunders et al. 100
(2003)). However it is not known if autoxidation may continue to form a second oxygen bridged radical, described
as type II autoxidation (Molteni et al., 2018, Fig 1, BZBIPERO2-diB), or form a hydroperoxide carbon centred
radical, formed through intra molecular hydrogen abstraction (type I autoxidation). At each step, termination of
the peroxy radical to hydroxyl, hydroperoxyl, nitrate, peroxy nitrate or reduction to an alkoxy radical is possible,
from which further termination via formation of a nitrite, nitro- or acyl group can occur. 105
Typically the presence of NOx alters the product distribution of VOC oxidation and reduces SOA formation (e.g.
Stirnweis et al. 2017). With other atmospherically relevant VOC precursors of SOA e.g. isoprene or
monoterpenes, high NO conditions can supress SOA formation (Wildt et al., 2014; Sarrafzadeh et al., 2016) as
reduction of RO2 to RO ultimately leads to fragmentation of the RO species (Surratt et al., 2006; Nguyen et al.,
2015), but it can also form epoxides, aldehydes and hydroperoxides which readily partition to the aerosol phase 110
and contribute to SOA growth (Surratt et al., 2010).
The further reaction of NOx with oxygenated VOCs produces species including nitro organics, nitrates, peroxy
nitrates and peroxyacyl nitrates (Atkinson, 2000) that can also condense and contribute to SOA formation. Under
conditions where NOx is present in moderate amounts, the HO2:OH ratio is low as HO2 is reduced by NO to form
OH. This allows more OH oxidation to occur and less termination of RO2 by HO2 to occur; whereas under low 115
https://doi.org/10.5194/acp-2020-819Preprint. Discussion started: 17 August 2020c© Author(s) 2020. CC BY 4.0 License.
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NOx conditions VOC consumption is lower, as OH recycling from HO2 relies on the slower HO2 + O3 reaction
(Atkinson, 2000). Here low and high NOx are relative terms and are defined by the available VOC. This reduction
of the HO2:OH ratio as a function of NO has been observed at Mace Head, Ireland where clean low NOx marine
influenced air can be contrasted with polluted NOx containing continental air (Creasey, Heard and Lee, 2002). In
that instance, an increase in NO concentration from 0.01 ppb to 1 ppb reduces the HO2:OH ratio from 200:1 to 120
10:1.
The autoxidation mechanism is known to form biogenic HOM, and as a consequence SOA, in ambient rural
environments (e.g. Ehn et al. 2014). The mechanism is increasingly a competitive process in urban and suburban
environments where NOx concentrations have seen significant reductions in recent years (Praske et al., 2018).
These low concentrations of NOx (0.1 - 1’s ppb) have been shown to enhance local oxidant production and drive 125
an increase in biogenic HOM formation (Pye et al., 2019). Aromatic HOM formation by OH at relevant urban
NOx concentrations has been demonstrated (Tsiligiannis et al., 2019; Zaytsev et al., 2019; Garmash et al., 2020;
Mehra et al., 2020).
ToF-CIMS is a measurement technique frequently used to probe VOC oxidation due to the ability to detect many
low concentration compounds simultaneously in real time (e.g. Chhabra et al. 2015). As a result of the sensitivity 130
of the nitrate ionisation scheme towards HOM, this reagent ion is typically used to study the autoxidation
mechanism and HOM formation. However, to achieve carbon mass closure of the system, multiple ionisation
schemes are required due to their complimentary yet differing sensitivities towards OVOCs with different
oxidation states and functional groups (e.g. Isaacman-VanWertz et al., 2017; Riva et al., 2019).
In this study, the oxidation of benzene by OH under atmospherically relevant high and low urban NOx conditions 135
is investigated in the Jülich plant atmosphere chamber (JPAC) with two time of flight chemical ionisation mass
spectrometers (ToF-CIMS) using the iodide and nitrate ionisation schemes. The properties of the oxidation
products are compared between the two ionisation schemes, as well as the high and low NOx conditions.
2. Methods and Experimental
The experiments were performed in a 1450 L borosilicate continuous flow reactor of the Jülich Plant Atmospheric 140
Chamber (JPAC) described elsewhere (Mentel et al., 2009). The chamber is operated in continuous flow mode in
order to homogenise the mixture giving an average residence time of ~45 minutes. Benzene (Merck, ≥ 99.7%)
was introduced into the chamber by flowing purified ambient air over a diffusion source to maintain a constant
concentration and was monitored by recording the inlet and outlet concentrations by quadrupole proton transfer
mass spectrometry (PTR-MS). The PTR-MS (IONICON) was calibrated using a benzene diffusion source 145
(Garmash et al., 2020). The difference between the outlet and inlet concentrations, measured at a 2 minute time
resolution and switched every 25 minutes, describes the reacted benzene, from which the OH concentration is
calculated.
Exp NOx /
ppb
Reacted Benzene /
ppb
J(O1D) /
10-3 s-1
JNO2 /
10-3 s-1
OH /
107 molecules cm-3
0 (Low NOx) ≤ 0.30 65.0 2.60 0.00 12.0
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1 (High NOx) 20.0
65.0 2.60 0.00 5.80
65.0 2.60 4.30 6.50
Table 1. Summary of selected experiments performed at JPAC used in this study. Two OH concentrations are reported for
the NOx containing studies. The first describes steady state concentrations with JNO2 (UVA) and ultra violet (TUV) light on, 150
the second with only the JNO2 (UVA) light on.
OH is generated by photolysis of O3 by a UV lamp (λ < 254 nm, Philips, TUV 40W herein termed TUV) and the
subsequent O(1D) reaction with H2O. O3 is introduced to the chamber by a separate line to the benzene in order
to prevent reactions occurring inline and was monitored by UV absorption (Model 49, Thermo Environmental
instruments). OH concentrations are calculated under steady state conditions (ss) according to the equation below 155
and are described in detail elsewhere (Garmash et al., 2020). The residence time in the chamber (t) was 2900
seconds and is equal to the chamber volume (V =1450 L) divided by the flow rate (F) of 30 standard litres per
minute (slm) and kBenzene+OH = 1.23x10-12 cm3 s-1.
[𝑂𝐻]𝑠𝑠 =[𝐵𝑒𝑛𝑧𝑒𝑛𝑒]𝑖𝑛 − [𝐵𝑒𝑛𝑧𝑒𝑛𝑒]𝑜𝑢𝑡
[𝐵𝑒𝑛𝑧𝑒𝑛𝑒]𝑖𝑛
1
𝑘𝐵𝑒𝑛𝑧𝑒𝑛𝑒+𝑂𝐻 (𝑉𝐹
)
NOx was measured by chemiluminescence (CLD 770 and PLC 760, Eco Physics). For the high NOx experiment, 160
NO (Linde, 99.5±5 ppm NO in N2) was injected into the chamber via a separate perfluoro alkoxy alkane (PFA)
line. Twelve discharge lamps termed UVA (HQI, 400 W/D; Osram, Munich, Germany) were activated to
photolyse NO2 (JNO2 = 4.3x10-3 s-1) to increase the NO/NO2 ratio, although NO2 remains the dominant NOx
compound at > 70% of total NOx. The TUV lamp was then switched on and then the UVA lamps switched off.
Temperature and humidity were maintained at 288±1 K and 67±2 % through the experiments. The experimental 165
conditions are summarised in Table 1.
It is expected that as the NOx concentration decreases, peroxy radical lifetime is much longer than the required
time scale for autoxidation hydrogen shifts (Praske et al., 2018) and so autoxidation products can be expected in
this low NOx case here (≤ 300 pptv). Where the UVA lamps are active, the NO/NOx ratio is increased, thus
increasing the ratio of RO/ROx (RO + RO2). 170
2.1. ToF-CIMS Instrumentation
Iodide
The University of Manchester ToF-CIMS has been described by Priestley et al. (2018). The iodide ToF-CIMS ion
molecule reaction region (IMR) was held at a constant pressure of 100 mbar by a scroll pump (Agilent SH-112)
controlled with a servo control valve placed between the scroll pump and the IMR. The short segmented 175
quadrupole (SSQ) region was held at 1.30 mbar by a second scroll pump (Triscroll 600). Chamber air was drawn
into the IMR via a critical orifice at 2.2 slm where it mixed with I- ions. The reagent I- ions were created by flowing
10 standard cubic centimetres per minute (sccm) of nitrogen (N2) over a methyl iodide (CH3I) permeation tube
made of 1/8” PFA and held at 40oC. This flow met 2 slm N2 and was flowed through a 210Po 10 mCi alpha emitting
reactive ion source (NRD Inc.). The mass calibration was performed for 7 known masses: NO3-, I-, I-.H2O, I-180
.HCOOH, I-.HNO3, I2- and I3
-, covering a mass range of 62 to 381 m/z. The mass calibration was fitted to a 3rd
order polynomial and was accurate to within 2 ppm, ensuring peak identification was accurate below 20 ppm. The
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resolution was 3231 at 127 m/z and 3720 at 381 m/z. The inlet to the I- ToF-CIMS sampled from the middle of the
chamber and was comprised of 50 cm 1/4” O.D. PFA tubing giving residency time of <1.5 s.
Formic acid calibrations and chamber and instrumental backgrounds were taken before every experiment to assess 185
instrument sensitivity changes. Backgrounds were performed by overflowing the CIMS inlet with N2 and
calibrations were performed by flowing 50 sccm N2 over a formic acid permeation tube held at 40oC. The formic
acid sensitivity was 3.15 ± 0.26 Hz ppt-1 (2σ) measured as a 5 minute average normalised to 106 Hz iodide. The
background was 2.72 ± 0.66 ppt (2σ) measured as a 5 minute average normalised to 106 Hz iodide. The limit of
detection (3σ) was 100 ppt. Calibration of all detected masses was not possible, so data are presented either as 190
signal (Hz) from the instrument or as a number of species.
It is not possible to identify a compound from its formula alone. Oxidation is initiated with OH addition to the
benzene ring, but fragmentation occurs and so the OH moiety may be lost; additionally multiple OH attacks make
the counting of oxygen more difficult (Garmash et al., 2020). It is for these reasons that RNOx species are
described more generally and any discussion of compound classes is speculative. Data analysis was performed 195
using the Tofware (V 3.1.0, (Stark et al., 2015) ).
Nitrate
The Jülich ToF-CIMS with nitrate ionisation is described elsewhere (Garmash et al., 2020). Chamber air was
drawn into an Eisele type inlet at 9 slm where it merges with a 20 slm sheath flow of nitrogen that contains nitrate
ions (NO3) for approximately 200 ms. These ions are generated by flowing 10 sccm dry nitrogen through a wash 200
bottle containing nitric acid (HNO3, Aldrich, 70%) that pass through a 241Am alpha emitting source. The inlet flow
enters the instrument through a 300 µm diameter aperture after which the ions are collimated and energetically
homogenised through a series of differentially pumped chambers.
Mass calibration is performed on nitrate, its dimer and trimer ions, NO3, NO3.HNO3 and NO3.(HNO3)2 and
hexafluoropentanoic acid (NO3.HFPA adduct) providing an accurate mass range up to 326 m/z. The resolution 205
was ~4000 at 125 m/z. The inlet to the instrument sampled from the middle of the chamber by a 1m 1/4” O.D
stainless steel tube.
2.2. Calculation of average carbon oxidation state (𝑶𝑺𝒄 )
Average carbon oxidation state 𝑂𝑆𝑐 (Kroll et al., 2011) is commonly used to describe the degree of oxidation
within a complex oxidation reaction. It is calculated using the oxygen to carbon ratio (O:C), hydrogen to carbon 210
ratio (H:C) and the nitrogen to carbon ratio (N:C) and assumes nitrogen is in the form of nitrate where the oxidation
state of N (OSN) is +5 :
𝑂𝑆𝑐 = (2 × 𝑂: 𝐶) − 𝐻: 𝐶 − (5 × 𝑁: 𝐶)
It is more difficult to justify this assumption for gas phase data and as this work explores different N-containing
functional groups, this nitrate assumption cannot be used. Instead of assuming all N is in the form of nitrate, a 215
range of OSN (5+, 3+ and 0) are considered and 𝑂𝑆𝑐 is calculated as a range from a theoretical minimum, where
all N is considered nitrate (5+), to a theoretical maximum, where all N is considered cyanate (0). Nitro and nitroso
compounds are also considered (3+), but amines and amides are not as they are not expected to be present in the
system. As neither the maximum or minimum OSN is a likely or an accurate description of the system, they merely
https://doi.org/10.5194/acp-2020-819Preprint. Discussion started: 17 August 2020c© Author(s) 2020. CC BY 4.0 License.
7
represent theoretical limits to calculate 𝑂𝑆𝑐 ; the true value will lie somewhere in the middle, in all likelihood 220
between the mean and lower limit as most species are expected not to be cyanates. The 𝑂𝑆𝑐 reported here is the
mean average of three scenarios where all N is considered to exist in 0, 3+ or 5+ oxidation states. This
methodology reduces the accuracy of the reported 𝑂𝑆𝑐 but it clearly and accurately presents the 𝑂𝑆𝑐
range.
In this document 𝑂𝑆𝑐 are reported as a function of carbon number. The variation in 𝑂𝑆𝑐
between all CHON of
the same carbon number is much greater than the variability in 𝑂𝑆𝑐 of a single CHON compound as a consequence 225
of varying OSN for that compound.
Where a species has the form RNO1,2 the species is considered to be either a cyanate or hydroxy cyanate and the
OSN is set to 0. For RNO3 species the nitrogen is considered to be either a dihydroxy cyanate or a hydroxy RONO
or RNO2 compound and so OSN is set to either 0 or 3+. RNO>3 have OSN set to 0, 3+ or 5+. This leads to the
modification of the 𝑂𝑆𝑐 parameterisation: 230
𝑂𝑆𝑐 = (2 × 𝑂: 𝐶) − 𝐻: 𝐶 − (𝑂𝑆𝑁 × 𝑁: 𝐶)
𝑂𝑆𝑁 = 0 𝑖𝑓 𝑛𝑂 = ≤ 2
𝑂𝑆𝑁 = [0, 3] 𝑖𝑓 𝑛𝑂 = 3
𝑂𝑆𝑁 = [0, 3, 5] 𝑖𝑓 𝑛𝑂 > 3
2.3. Hierarchical Cluster Analysis (HCA) 235
Hierarchical cluster analysis (HCA) is an analytical technique used to simplify datasets containing large numbers
of individual observations into groups or clusters defined by their similarity with the aim of increasing
interpretability of the dataset. HCA is an agglomerative technique which allows for the successive merging of
individuals or clusters to form larger clusters. Due to the complex nature of atmospheric oxidation and the
detection of many oxidation products by mass spectrometry, it is common practice to reduce the dimensionality 240
of mass spectrometry datasets in order to better describe bulk properties of the process being studied (Sekimoto
et al., 2018; Isokääntä et al., 2019; Koss et al., 2019) with HCA being one such method. HCA is independent of
calibration as it relies on relative differences between time series’ rather than exact concentrations, making it a
suitable technique to apply to mass spectrometry data where authentic standards do not exist and individual
calibrations are next to impossible. The final number of clusters is selected based on the distance between them 245
and is determined by the user. Here we use HCA to group the time series’ of benzene oxidation products to
investigate its utility as a tool for investigating oxidation processes or product properties where the reaction occurs
in a continually stirred flow reactor.
In order to use HCA the linkage criterion and distance metric must be selected. The root of the sum of the squares
of a pair of observations (time series), A and B, (i.e. the Euclidean distance) is chosen as the distance metric to 250
define the similarity of the time series’ at each time step, t.
𝑑𝐴,𝐵 = √∑(𝐴𝑡 − 𝐵𝑡)2
𝑡
The Ward linkage criterion was chosen to determine the distance between sets of observations (U, V, which can
be single or multimember clusters) as it gave similar or more interpretable results compared with other linkage
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8
criteria. Here, the sum of the squares of the cluster members (xi where i iterates over the members U, V or their 255
agglomeration) from their cluster means (mU, mV or mU∪V) are calculated. This is performed for the two candidate
clusters for agglomerating (U, V) and for the new cluster they would form through agglomeration (U∪V). The
difference in the sum of the squares between this potential merged cluster and the initial two candidate clusters is
the distance used to assess whether the agglomeration of the candidate clusters is acceptable:
𝑑𝑈,𝑉 = ∑ ‖𝑥𝑖 − 𝑚𝑈∪𝑉‖2
𝑖∈𝑈∪𝑉
− ( ∑ ‖𝑥𝑖 − 𝑚𝑈‖2
𝑖∈𝑈
− ∑ ‖𝑥𝑖 − 𝑚𝑉‖2
𝑖∈𝑉
) 260
When the increase in the sum of the squares (i.e. distances) is minimal after agglomerating, the two candidate
clusters, the new cluster is formed. Here, the time series for all CHO and CHON compounds from the iodide ToF-
CIMS measurements were selected for clustering. Time series were scaled between 0-1 to remove the effect of
their differing magnitudes and focus on the changes in trends. The scaled time series were then smoothed to a 10
minute average to remove noise that may affect the results of the HCA. This treatment is similar to other studies 265
using HCA with mass spectrometric data (e.g. Koss et al., 2019). The analysis was implemented using the
cluster.hierarchy module from SciPy (1.2.0) scientific python library using Python 3.6.
3. Results and Discussion
We detect a range of benzene oxidation products, including many with the same formula as those listed in the
MCM, as well as highly oxidised species with both ToF-CIMS instruments. Well resolved peaks at a given unit 270
mass were frequently observed in the I- spectrum. The separation between the I- ion cluster with its large negative
mass defect and the positive defect (excess) of the high H containing deprotonated species allows good peak
separation at the resolution of the ToF-CIMS (Fig 2). Beyond I- and H2O, the largest adduct signals we identified
with the I- CIMS were low mass species: formic acid (CH2O2), nitric acid (HNO3), CH2O3, C3H6O3, HONO,
C4H4O3 and C3H8O3. The prevalence of these ions is likely do to instrument sensitivity rather than chemistry. 275
3.1. Product distributions
3.1.1. CHON product distributions: comparison between nitrate and iodide ionisation
Forty-two formulae are found to be common in the low NOx experiment between the two instruments representing
the overlap of oxidation product signals of which 20 are C6 compounds and the rest have lower carbon numbers.
The time series behaviour of the signals at the start of oxidation is highly variable and is specific to each instrument 280
and ion measured by that instrument as oxidant levels and wall partitioning equilibrates. Typically, the level of
highly oxidised species increases significantly from the outset but relaxes to lower levels rapidly before they grow
again to reach steady state. This early spiking behaviour has been observed in other studies investigating VOC
oxidation using the nitrate ToF-CIMS (e.g. Ehn et al. 2014) and is thought to be a consequence of a latent aerosol
sink shifting the equilibrium species from the gas to the aerosol phase. The early spiking also describes the 285
dynamic nature of oxidation concentrations (OH and O3) before the steady state is reached. The iodide CIMS
measures a delayed response from wall equilibration processes (Krechmer et al., 2016; Pagonis et al., 2017)
making the detection of these rapid changes more challenging. For the range of species measured here, the
variability between the two measurements for the same species vary (Fig S1). In general the nitrate observes
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square waveforms whereas the iodide observes saw tooth waveforms. Where the agreement is particularly bad it 290
is most likely that different isomers contribute to the different signals measured on the two instruments.
The nitrate ionisation scheme detects a greater number of higher mass species with a higher oxygen content (Fig
3c, 3e) and higher OSc (Fig 3h, 0.84 vs 0.42), whereas the iodide ionisation scheme detects lower mass compounds
with a lower oxygen number and lower OSc, as has been reported elsewhere in different VOC oxidation systems
(e.g. Isaacman-VanWertz et al., 2017). The average mass of a nitrate adduct (not including the reagent ion) is 295
~240 g mol-1 with ~30% of that attributable to oxygen, whereas the average mass of an iodide adduct is 140 g
mol-1 with ~20% attributable to oxygen (Fig 3g).
The nitrate CIMS is able to detect a greater number of high mass species greater than C6 including a large number
of dimers (C12) whereas the iodide scheme did not detect many species greater than C6 in this instance but did
measure a greater number of low C molecules compared to the nitrate (Fig 3a). Few species greater than C12 are 300
detected with either reagent ion, suggesting that in this system, their formation was not likely, as both the nitrate
and iodide ionisation schemes are capable of detecting >C20 compounds (e.g. Mohr et al., 2019). The iodide
scheme detects a maximum number of molecules containing O3 and O4 and very few with more than O7 (Fig 3c).
The nitrate scheme observes a broad range of oxygen numbers peaking between O9 and O11 but up to O18. Iodide
detects an average H:C/O:C of ~1.5 whereas nitrate detects H:C/O:C of approximately 1.1 due to higher O:C 305
ratios (Fig 3f).
With both nitrate and iodide ionisation, the maximum variation in oxygen number per molecule is detected for C6
compounds (Fig 4a) although for nitrate this is closely followed by C12 i.e. C6 dimers as well as C5, C9 and C10
compounds. The nitrate CIMS detects approximately half the number of low oxygen content (O2-4) (and N
containing) oxidation products compared to the iodide CIMS. Subsequently, OS𝐶 as a function of carbon number 310
differs between the ionisation schemes at higher carbon numbers (Fig 4b). Below C8 the OS𝐶 broadly agree
however above C8 the iodide observes negative OS𝐶 whereas nitrate observes positive values. This is likely due
to the detection of different isomers, which become more prevalent at these at these higher masses.
The saturation concentrations (C*) of the detected species were calculated using the relation of Mohr et al. (2019).
The C* indicates that there is significant overlap of SVOC and IVOC detection between the two instruments (Fig 315
4c). Whilst the iodide ionisation scheme detected HOM, it did not detect any ELVOC (extremely low volatile
compounds) and very little LVOC (low volatile compounds), detecting instead mainly IVOC (intermediate
volatile compounds), SVOC (semi volatile compounds) and some VOC (Fig 4c). This is in contrast to the nitrate
scheme which detected mainly ELVOC, SVOC and some IVOC, although less than the iodide. This highlights
that sampling with both nitrate and iodide schemes captures a large range of gas phase oxidation products, as has 320
been shown in other systems (e.g. Riva et al., 2019).
3.1.2. Iodide CIMS detected CHO and CHON under different NOx conditions
A total of 132 and 195 adduct and deprotonated peaks identified as CHO or CHON in the low and high NOx
experiments respectively using the iodide CIMS of which 126 are common between the experiments (Fig 5). The
number of detected compounds is much higher in the high NOx case compared with the low NOx case. This is 325
expected as the complexity of the system increases and additional reaction pathways are viable. This is especially
true regarding the detection of N containing compounds. As the chamber had a NOx background of ~ 300 ppt,
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formation of N-containing compounds still occurred during the low NOx experiment. Twenty four N-containing
products were detected during the low NOx experiment compared with 70 detected during the high NOx
experiment (20 ppb NOx) of which 23 were common. 330
The majority of species detected are C6 and C4 compounds (Fig 6a) in both cases with O3-4 also most abundant.
The atom distributions (Fig 6 a-d) appear very similar, with the largest difference being the number of detected N
containing compounds (Fig 6 d), where more than twice as many are detected in the high NOx case. The average
carbon and hydrogen atom number for the detected species is marginally higher for the low NOx case than for the
high NOx case (Fig 6e). This observation is further enhanced when weighting the average composition by signal 335
rather than merely counting detected species. This is consistent with greater fragmentation occurring under higher
NOx conditions and is also reflected in the average masses of the reaction products when signal weighted (Fig
6g). The O:C and H:C ratios are very similar between the two experiments (H:ClowNOx = 1.34 and O:ClowNOx = 0.93
compared with H:ChighNOx = 1.34 and O: ChighNOx = 1.02, Fig 6h) and is reflected in OS𝐶 , which is marginally
higher in the high NOx case (0.36 vs. 0.42) although the range of possible OS𝐶 for both experiments have 340
significant overlap (0.31 - 0.42 for the low NOx case and 0.28– 0.60 for the high NOx case, Fig 6h). The small
differences in oxidation product characteristics between the two NOx conditions indicates bulk analysis of all
oxidation products is not sensitive enough. In order to better understand the differences between oxidation
products from the different NOx cases, the ions are grouped by preference to formation under high or low NOx
conditions (defined as the regime in which signal enhancement is greatest) and re-analysed (Fig S2). Despite 345
having a very similar average mass, those products that preferentially formed under high NOx conditions have a
lower OS𝐶 < 0.13 compared to the low NOx conditions where OS𝐶 ~ 0.39.
In order to better describe these oxidation products, five different groupings of compounds are used to categorise
detected oxidation products. Background species refer to those present in the chamber before oxidation and
comprise < 0.05 % of total signal. Compounds of formulae that match species described in the benzene oxidation 350
mechanism of the MCM are denoted MCM and comprise 7.3 % and 6.4 % of the low and high NOx experiments
respectively. Highly oxidised products are identified as species containing 6 or more oxygen atoms and comprise
0.26 % and 0.05 % of the low and high NOx experiments respectively. These highly oxidised products can include
ring breaking and ring retaining products. The rest of the products are termed remainder and are either ring
retaining or ring breaking based on the number of carbon atoms present. Where 6 carbon atoms are present and 355
the double bond equivalent (DBE) equals 4 then the species is ring retaining and where it is less it is defined as a
ring breaking product (Mehra et al., 2020). Remaining ring breaking products make up the most of the remaining
signal at 89 % and 91 % of the low and high NOx experiments respectively leaving ring retaining products
contributing 3.6 % and 2.5 % to the low and high NOx experiments respectively.
MCM and ring breaking products are observed to grow continually over the time period of oxidation, whereas 360
highly oxidised and ring retaining products equilibrate and remain flat for the duration of the experiment (Fig 7).
This is also true of the high NOx experiment, although when NO2 photolysis stops halfway through the oxidation,
the growth of signal is diminished and the saw tooth profile less apparent. The MCM and ring breaking groups
contain small, oxidised molecules that are near the end of the oxidative chain representing large sink of the carbon
in the system and so continually grow. The ring retaining and highly oxidised species reach an equilibrium quickly 365
as they tend to be earlier generation products and so their profiles remain flat.
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3.2. MCM products
The MCM lists 85 multigenerational oxidation products of benzene including important intermediate and radical
species (Jenkin et al., 2003; Bloss et al., 2005). The iodide ToF-CIMS detects 19 and 26 of these oxidation
products under low and high NOx conditions. These signals are a mixture of adducts and non-adduct peaks that 370
match the exact masses of the MCM oxidation products to within 20 ppm error. Whilst only 19 and 26 of the
species with a formula cited in the MCM are detected, signals increase for 132 and 195 peaks in the mass spectrum
under low and high NOx conditions respectively indicate many more products are formed than are explicitly
accounted for.
The iodide CIMS is able to observe 25 % and 30 % of the listed MCM compounds in the low and high NOx 375
conditions respectively (Fig 8). The distributions of the number of detected C, H, O and N broadly follows the
available MCM C, H, O and N, for example the number of C3 and C5 compounds in this reaction scheme are much
fewer than C2,4,6 which is reflected proportionally in the number of detected species. This suggests that distributed
over the entire mechanism, there is no preference for detection of any specific CHON configurations. A list of all
detected species can be found in table S2. 380
3.3. Mechanistic investigation
To test the extent to which the iodide CIMS is able to detect highly oxidised molecules that may originate from
autoxidative processes, a number of theoretically suggested formulae based on the autoxidation mechanism with
propagation and termination steps were devised and then searched for within the spectra. The applied mechanism
includes the benzene oxidation scheme from the MCM with two additional autoxidation steps added in. It consists 385
of autoxidative intra molecular hydrogen shifts from the carbon backbone to a peroxy radical group forming a
hydroperoxide group, followed by O2 addition to form a new peroxy radical (Fig 1). The peroxy radical groups
were terminated to hydroxyl, peroxyl, nitrate or peroxy nitrate groups, or reduced to form the alkoxy equivalent
which then terminates to a carbonyl group or a nitro group (isomeric with nitrite). This was repeated for phenol
and catechol precursors providing a total of 53 individual oxidation products with 21 unique formula. We observe 390
14 and 21 individual deprotonated and adduct signals in the low and high NOx spectra that correspond to 9 and
11 unique formula respectively. These 9 and 11 unique formula correspond to a maximum of 27 and 33 individual
oxidation products (Table S1).
At least one signal (adduct or deprotonated) for all theoretic CHO products are observed in the low NOx case apart
from C6H8O9 and C6H8O10. No derived CHON are observed in the low NOx case indicating the incorporation of 395
nitrogen into compounds observed under these conditions occurs at a later point. C6H8O6, C6H8O7, C6H8O8 can
only be formed through the autoxidation mechanism from either phenol or catechol precursors. All three are found
in the low NOx case and C6H8O7 and C6H8O8 are found in the high NOx case. C6H8O8 is an exclusively second
generation autoxidation product that has been observed previously in benzene oxidation studies (Molteni et al.,
2018). C6H8O9 and C6H8O10 are not observed in the high NOx case. C6H7NO4, C6H7NO6, C6H7NO7, are the only 400
NOx containing species observed in the high NOx case. The formation of C6H7NO4 has two mechanistic routes,
the nitration of the initial hydroxy benzene peroxy radical or the addition of a peroxy nitrate group to the phenol,
whereas C6H7NO6, C6H7NO7 have numerous routes to formation with the only non-autoxidation route being the
nitration of phenol and catechol respectively. Exclusively second generation high oxygen content CHON species
C6H7NO8, C6H7NO9, C6H7NO10, C6H7NO11 are not observed. Figure 9 summarises these ions in the mass spectra. 405
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3.4. Ring retention and ring breaking products
In terms of signal, most of the ring retaining products are O1,2,3 of which O1,2 is dominated by the formation of
phenol and catechol. Conversely, O3 isn’t dominated by any one product, but instead comprises of both CHO and
CHON products in both NOx conditions (Fig 10). Although O1-7 species are observed in both cases, higher O 410
numbers of 10, 11 and 12 are only visible in the high NOx case due to the presence of nitrogen groups that can
incorporate more oxygen.
For the ring breaking products, the majority of signal can be attributed to the presence of species containing 3 and
4 oxygen atoms, although at lower carbon numbers of 1 and 2 lower oxygen numbers of 1 and 2 become important
(Fig 11). The majority of signal for both cases is due to C1,2,3 compounds. C3 compounds show the greatest signal 415
contribution for the largest range of oxygen numbers. This is especially true in the high NOx case where signal C3
compounds have a greater contribution from O>4. Similarly at higher carbon numbers e.g. 5 and 6, higher oxygen
numbers of between 6 and 12 are more readily observed, again where N is incorporated in the high NOx case a
greater inclusion of oxygen is also observed. The form of this organic nitrogen is perturbed throughout the
experiment by altering the NO/NOx fraction by photolysing NO2. 420
3.5. Effect of NO2 photolysis during oxidation under high NOx conditions
A four cluster solution was chosen from analysis of the dendrogram (Fig S3) and is sufficient to provide enough
detail that can be explained, but not so much that interpretation becomes unclear. Further refinement of clusters
greater than 4 offers no more insight in time series behaviour due to oxidation behaviour but rather describes
signal delay likely due to gas wall partitioning (Krechmer et al., 2016; Pagonis et al., 2017). This behaviour is 425
still observed in the four cluster solution, however other affects pertaining to chemistry rather than partitioning
are more visible at this low cluster number. Therefore the four cluster solution is chosen (Fig 12). See Table S2.
for a list of MCM defined products and their assigned clusters.
Cluster 3 and cluster 4 do not display much effect of NO2 photolysis. Cluster 3 is a slow formation cluster that
grows as photo-oxidation begins. This is likely to represent semi-volatile material that partitions to walls and 430
equilibrates with the instrument lines and IMR. Cluster 4 is a background cluster that decays when photo-oxidation
begins (TUV on) and recovers when photo-oxidation stops. These species make up 2.75 % of the total signal
during oxidation and so are thought not to contribute majorly to the reaction. The background cluster 4 has the
lowest number of RNOx containing members, and the slow growth, semi-volatile cluster 3 has the greatest number
(Fig 13c). Cluster 4 contains the greatest number of species with high carbon numbers with a negative OS𝐶 . These 435
characteristics are reflected in cluster 3 but to a lesser extent as carbon numbers are smaller and OS𝐶 less negative.
It is also notable that cluster 1 products remain at elevated levels in the chamber after all photochemistry has
stopped. This again may be indicative of more semi volatile material formed. This is anecdotally corroborated by
the higher oxygen and carbon numbers of cluster 1 compared to cluster 2 (Fig 13a). Cluster 2 shares time series
features that are similar to clusters 1 and 3. It has the same long range response as cluster 3 but the same short 440
range increase from photo-oxidation as cluster 1. This is reflected in Fig. 13b where cluster 2 overlaps with clusters
1 and 3, which themselves are well separated. Both these clusters have lower average carbon numbers and higher,
positive OS𝐶 compared with clusters 3 and 4 (Fig 13b).
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Clusters 1 and 2 represent the formation of oxidation products. They increase similarly when photo-oxidation is
initiated, however when the NO2/NOx ratio is increased, cluster 1 continues to increase but cluster 2 decreases. 445
This suggests cluster 1 products are independent of NO2/NOx ratio at these high NO2 fractions; the growth curve
is independent of the decrease in NO concentration, suggesting this cluster is characterised by more reactions of
NO2 and peroxy radicals. Conversely to cluster 1, cluster 2 decreases when the NO2/NOx increases suggesting NO
is an important route to formation, either from NO addition products or the increased alkoxy radical fraction
RO/RO2, which is supported by cluster 2 products having higher OS𝐶 and lower carbon numbers than cluster 1 450
products.
Both clusters 1 and 2 contain a similar number of RNO and RNO2 species, but cluster 1 has a greater, odd number
of oxygen as RNO3 and RNO5, whereas cluster 2 has a greater even number of oxygen in RNO4 and RNO6. The
inclusion of these groupings in one cluster leads to a lack of them in the other; no RNO4 or RNO6 are found in
cluster 1 nor is there a large amount of RNO5 or any RNO3 in cluster 2. 455
Ideally, NO and NO2 addition to peroxy precursors (cluster 1) would produce nitrates and peroxy acyl nitrates
(PANs) that have an odd number of oxygens (RNO3 and RNO5), and addition to alkoxy precursors (cluster 2)
would produce nitro- and nitrite compounds that have an even number of oxygens (RNO2). This is indeed
observed, however in reality this distinction is not so clear cut as OH addition vs abstraction would reverse this.
So although these observations are broadly followed, they are not exact resulting in a blurring of RNOx groupings, 460
especially at higher O numbers (Fig 13c). Both clusters 1 and 2 have the same number of RNO7 species despite
their time series profiles showing a different dependency on the NO2/NOx ratio. It is likely that these RNO7 are
structurally different and the oxygen is incorporated into their structures in different ways. For example cluster 1
RNO7, which are all C5 and C6 compounds, may contain more PAN like compounds as these are formed from
peroxy acyl radicals and NO2 addition e.g. to BZEMUCCO3 (MCM), which is the peroxy radical formed from 465
BZEPOXMUC, a first generation ring opening product of benzene, to form BZEMUCPAN (C6H5NO7). In
contrast, cluster 2 RNO7 are smaller C3 and C4 compounds, which may require the fragmentation of larger organic
precursors enhanced by the presence of NO e.g. the unimolecular decomposition of the alkoxy radical
MALANHYO to form HCOCOHCO3 and then HCOCOPAN (C3H3NO7).
4. Conclusion 470
Two ToF-CIMS using iodide and nitrate ionisation schemes were deployed at the Jülich plant chamber as part of
a series of experiments examining benzene oxidation by OH under atmospherically relevant high (20 ppb) and
low (0.3 ppb) NOx conditions.
Both ionisation schemes detect benzene oxidation products including highly oxidised organic molecules. Nitrate
CIMS detects many C12 dimers and a greater number of species with high oxygen (O9-O11). This translates to 475
higher OS𝐶 , especially at higher carbon numbers (C≥8), and lower C* indicating the detection of ELVOC, SVOC
and IVOC. In contrast, the iodide CIMS detects no dimers, but many more monomers and ring breaking products
(C≤6) than the nitrate scheme, with most common oxygen numbers of (O3-O4). The OS𝐶 of high carbon species is
lower, although at lower carbon numbers (C<6) OS𝐶 between the two ionisation schemes broadly agree due to the
increased likelihood of measuring the same species, rather than isomers. The corresponding C* measured by the 480
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iodide CIMS suggests no ELVOC was detected, but many more SVOC, IVOC and some VOC were measured
when compared to the nitrate CIMS. Thus the two ionisation schemes cover a large range of volatilities.
132 and 195 CHO and CHON species are detected in the low and high NOx experiment respectively of which 126
are common. In both cases these are mostly C4 and C6 compounds. A greater number of oxidation products are
measured in the high NOx case, including 70 N containing compounds compared to 24 in the low NOx case, of 485
which all but one are common. Splitting oxidation products into five categories, the contribution to signal
increases sequentially from: background (< 0.05 %), highly oxidised products (0.05 - 0.26 %), ring retaining (2.5
– 3.6 %), MCM (6.4 – 7.3 %), and ring breaking (89 – 91%). The 6.4 – 7.3 % of signal assigned to MCM products
represents 25 – 30 % of the 85 listed multigenerational oxidation products detected under low and high NOx
conditions and are proportionally distributed across all carbon numbers. Highly oxidised and ring retaining 490
products equilibrate quickly within the system and remain throughout the experiments, whereas MCM and ring
breaking products continue to grow throughout the experiments. Highly oxidised and ring retaining products are
earlier generation products which form quickly and equilibrate as loss and formation processes equalise. MCM
and ring breaking products contain smaller, more oxidised molecules that are further down the oxidation chain
and represent the largest destination of carbon within the system. Signal from ring retaining products is dominated 495
by phenol (O1) and catechol (O2) whereas O3 compounds comprise a number of different species. Ring breaking
products are dominated by C1, C2 and C3 compounds with similar oxygen numbers. C3 compounds show the
greatest variability of oxygen atom number. For both retention and breaking products, high O numbers of up to 7
are identified, however in the high NOx case where incorporation of RNOx is greater, higher O numbers of 10, 11
and 12 are observed. Within the context of the theoretical mechanistic investigation (section 3.3), iodide ionisation 500
is able to detect 27 and 33 species belonging to potential autoxidation reaction pathways. These detected species
include one previously observed, exclusively second generation autoxidation product C6H8O8 and all derived 1st
generation autoxidation products. However it is noted that only two of these first generation products steps
(C6H8O6, C6H8O7) are formed exclusively through autoxidation whilst the rest have other routes to formation.
Higher oxygen content products C6H8O9 and C6H8O10 are not observed in either case. 505
Clustering the time series in the high NOx experiment into four clusters distinguishes two clusters that contain
products formed from photo-oxidation. One of these clusters (cluster 1) is independent of the NO2/NOx ratio
whereas a second cluster (cluster 2) decreases, as a result of NO dependent formation, either through addition
and/or an increased RO/RO2 fraction. Cluster 2 has higher OS𝐶 and lower carbon numbers than cluster 1
suggesting it consists of more oxidised and fragmented compounds consistent with an increased RO/RO2. Cluster 510
2 contains RNO4 and RNO6 but no RNO3 and little RNO5 whereas the opposite is true for cluster 1. This somewhat
agrees with theoretical RNOx product distributions as NOx addition to alkoxy radicals (cluster 2) is more likely to
produce even oxygen content RNOx (through the formation of nitrites and nitro compounds), and odd oxygen
RNOx through addition to peroxy radicals (cluster 1, such as nitrates and PANs). For species with larger oxygen
content e.g. RNO7 which is detected in both clusters, the carbon number is lower for cluster 2 (C3,4) compared to 515
cluster 1 (C5,6) indicating more fragmentation has occurred, again implying a greater contribution from the alkoxy
channel. It is noted that the effect of OH addition rather than H abstraction as the initiation step to the reaction
will reverse this pattern, and along with other unimolecular rearrangements, may explain some of the RNOx cluster
variability observed.
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Contributions 520
MP analysed nitrate and iodide ToF-CIMS data and wrote the manuscript. OG analysed nitrate ToF-CIMS data
and provided peaklist data. TJB and MLB operated the iodide CIMS. DES, AM, SDW and AB contributed to
iodide CIMS analysis with oversight of CJP and HC. CJP and GM led the development of the experiments
presented here. TFM, AKS, CJP, MH, GM, ÅH designed the experiments. SK, IP, SS, RT, EK, DZ, JW operated
the nitrate CIMS and performed the experiments. 525
Acknowledgements
This work was conducted during a PhD study supported by the Natural Environment Research Council (NERC)
EAO Doctoral Training Partnership and is fully-funded by NERC whose support is gratefully acknowledged
(Grant ref no. NE/L002469/1).The study was funded by European Research Council grant 638703 and supported
by Doctoral School in Atmospheric Sciences at the University of Helsinki (ATM-DP). This work was supported 530
by the Swedish Research Council (grant number 2014-5332). Å.M.H. acknowledges Formas (grant number 214-
2013-1430) and Vinnova Sweden’s Innovation Agency (grant number 2013-03058), including support for her
research stay at Forschungszentrum Jülich. Part of the research in this study was performed at the Jet Propulsion
Laboratory, California Institute of Technology, under a contract with the National Aeronautics and Space
Administration. 535
Competing Interests
The authors declare no competing interests.
Data Availability
Data is available on request.
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Figure 1. Reaction scheme of benzene oxidation by OH with proposed di-bridged species adapted from Molteni et al.,
(2018). Species present in the MCM are labelled.
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700
Figure 2. Example of peak separation between an iodide adduct I.C2H2O3- and deprotonated signal C10H17O4
- detected during
background measurements before the low NOx experiment.
Figure 3. Summary of CHO and CHON statistics of detected oxidation products during the high (20 ppb) NOx benzene
oxidation for iodide (purple) and nitrate (green) ionisation schemes. (a, b, c, d.) Frequency distributions of the atoms C, H, O 705
and N for the detected oxidation products. (e) Average number of atoms per detected oxidation product split into C, H, O
and N. (f) Van Krevelen diagram (O:C vs H:C). (g) The average mass of a detected oxidation product detected by iodide and
nitrate ionisation. (h) The average carbon oxidation state OS𝐶 of oxidation products detected by iodide and nitrate ionisation.
Limits represent minimum and maximum OS𝐶 as a function of minimum and maximum OSN, see section 2.3.
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710
Figure 4. Comparison of organic oxidation products from the iodide (purple) and nitrate (green) ionisation schemes. (a)
carbon number vs oxygen number. (b) average carbon oxidation state (OS𝐶) vs carbon number. (c) Saturation concentration
(C*) based on Mohr et al. (2019).
Figure 5. (a) Unit mass spectrum during benzene oxidation by OH under (a) low NOx conditions and (b) under high NOx 715
conditions. Identified CHO and CHON compounds are highlighted.
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Figure 6. Summary of CHO and CHON statistics of detected oxidation products during high (20 ppb, grey) and low (0.3
ppb, purple) NOx benzene oxidation with the iodide ionisation scheme. (a, b, c, d.) Frequency distributions of the atoms C,
H, O and N for the detected oxidation products. (e.) The average number of atoms per detected oxidation product split into 720
C, H, O and N atoms, also shown is signal weighted average atom number. (f.) Van Krevelen diagram (O:C vs H:C) sized by
signal. (g.) The average mass of a detected oxidation product for high and low NOx conditions, also shown signal weighted
average masses. (h.) The mean, average carbon oxidation state (OS𝐶) of the detected oxidation products for high and low
NOx conditions. Limits represent minimum and maximum OSC as a function of minimum and maximum OSN, see section
2.3. 725
Figure 7. Total signal from CHON + CHO compounds for the low NOx (a) and high NOx (b) experiments. (c) and (d) show
the same data in (a) and (b) with a reduced y scale; y and x scale have the same units.
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Figure 8. Fraction of ions observed from the MCM in the high and low NOx experiments expressed as number of molecules 730
containing atom numbers for (a) carbon, (b) oxygen and (c) nitrogen.
Figure 9. Unit mass spectra of (a) low NOx and (b) high NOx experiments. Detected ions from the mechanism are
highlighted as CHO (blue) or CHON (red). 735
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Figure 10. Normalised signal fraction of ring retaining products under high and low NOx conditions. Signal for phenol and
catechol dominate for both conditions and make up the O1 and O2 fractions.
Figure 11. Signal fraction as a function of carbon number for ring breaking products for the (a) high NOx and (b) low NOx 740
conditions.
Figure 12. Time series of the four cluster means for the high NOx experiment. Clusters 3 and 4 represent slow formation and
background clusters and give no information regarding the effect of NO2 photolysis. Clusters 1 and 2 display similar
behaviours when the TUV light is switched on, but different behaviours when the UVA light is switched off, indicating their 745
members are sensitive to the change NO/NOx ratio determined by the UVA light state. The shaded area is the dark state
before any photolysis occurs.
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Figure 13. Cluster characteristics (a) carbon vs oxygen number (b) carbon number vs average carbon oxidation state. Squares
indicate cluster averages. (c) Number of RNOx species. Clustering based on time series similarity provides good separation 750
in OS𝐶 vs C space (b) and splits RNOodd and RNOeven in clusters 1 and 2 (c).
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